CY7C4205-25ASC中文资料
64, 256, 512, 1K, 2K, 4K x 18 Synchronous FIFOs
fax id: 5410
CY7C4425/4205/4215 CY7C4225/4235/4245
Features
?High-speed, low-power, first-in first-out (FIFO) memories
?64 x 18 (CY7C4425)?256 x 18 (CY7C4205)?512 x 18 (CY7C4215)?1K x 18 (CY7C4225)?2K x 18 (CY7C4235)?4K x 18 (CY7C4245)
?High-speed 100-MHz operation (10 ns read/write cycle time)
?Low power (I CC =45 mA)
?Fully asynchronous and simultaneous read and write operation
?Empty, Full, Half Full, and Programmable Almost Empty/Almost Full status flags ?TTL-compatible
?Retransmit function ?Output Enable (OE) pin
?Independent read and write enable pins
?Center power and ground for reduced noise
?Supports free-running 50% duty cycle clock inputs ?Width Expansion Capability ?Depth Expansion Capability
?Space saving 64-pin 10x10 TQFP , and 14x14 TQFP ?68-pin PLCC
Functional Description
T he CY7C42X5 are high-speed, low-power, first-in first-out
(FIFO) memories with clocked read and write interfaces. All are 18 bits wide and are pin/functionally compatible to IDT722x5. The CY7C42X5 can be cascaded to increase FIFO depth. Programmable features include Almost Full/Almost Empty flags. These FIFOs provide solutions for a wide variety of data buffering needs, including high-speed data acquisition,multiprocessor interfaces, and communications buffering.These FIFOs have 18-bit input and output ports that are con-trolled by separate clock and enable signals. The input port is
controlled by a free-running clock (WCLK) and a write enable pin (WEN).
When WEN is asserted, data is written into the FIFO on the rising edge of the WCLK signal. While WEN is held active, data is continually written into the FIFO on each cycle. The output port is controlled in a similar manner by a free-running read clock (RCLK) and a read enable pin (REN). In addition, the CY7C42X5 have an output enable pin (OE). The read and write clocks may be tied together for single-clock operation or the two clocks may be run independently for asynchronous read/write applications. Clock frequencies up to 100 MHz are achievable.
Retransmit and Synchronous Almost Full/Almost Empty flag features are available on these devices.
Depth expansion is possible using the cascade input (WXI,RXI), cascade output (WXO, RXO), and First Load (FL) pins.The WXO and RXO pins are connected to the WXI and RXI pins of the next device, and the WXO and RXO pins of the last device should be connected to the WXI and RXI pins of the first device. The FL pin of the first device is tied to V SS and the FL pin of all the remaining devices should be tied to V CC . The CY7C42X5 provides five status pins. These pins are de-coded to determine one of five states: Empty, Almost Empty,Half Full, Almost Full, and Full (see Table 2). The Half Full flag shares the WXO pin. This flag is valid in the standalone and width-expansion configurations. In the depth expansion, this pin provides the expansion out (WXO) information that is used to signal the next FIFO when it will be activated.
The Empty and Full flags are synchronous, i.e., they change state relative to either the read clock (RCLK) or the write clock (WCLK). When entering or exiting the Empty states, the flag is updated exclusively by the RCLK. The flag denoting Full states is updated exclusively by WCLK. The synchronous flag archi-tecture guarantees that the flags will remain valid from one clock cycle to the next. As mentioned previously, the Almost Empty/Almost Full flags become synchronous if the V CC /SMODE is tied to V SS . All configurations are fabricated using an advanced 0.65μ N-Well CMOS technology. Input ESD protection is greater than 2001V, and latch-up is prevent-ed by the use of guard rings.
元器件交易网https://www.360docs.net/doc/017932655.html,
Logic Block Diagram
42X5–1
THREE–ST ATE OUTPUT REGISTER
READ CONTROL
FLAG LOGIC
WRITE CONTROL
WRITE POINTER READ POINTER
RESET LOGIC
EXPANSION LOGIC
INPUT REGISTER
FLAG PROGRAM REGISTER
D 0
–17
REN
RCLK FF EF PAE Q 0
–17
WEN
WCLK RS
FL/RT WXI OE
DUAL PORT RAM ARRAY 64x 18256x 18512x 181K x 182K x 184K x 18
PAF WXO/HF
RXI RXO
SMODE
Pin Configurations
Top View
Q 14Q 13GND Q 12Q 11V CC Q 10Q 9GND Q 8Q 7V CC D D D D D V Q 6Q 5GND Q 4
V CC /SMODE PLCC Q 15
G N D Q 16
Q 17
V C C
E F
G N D
V C C
R S O E L D R E N R C L K G N D
D 17
D 16
D 15
D 14D 13D 12D 11D 10D 9D 8D 7D 6D 5D 4D 3D 2D 1D 0
D 15P A E
W C L K W E N W X I V C C
P A F R X I F F W X O /H F R X O
Q 0
Q 1
G N D Q 2
Q 3
Q 14Q 13GND Q 12Q 11V CC Q 10Q 9GND Q 8Q 7Q 6Q 5GND Q 4V CC
F L /R T
Selection Guide
7C42X5-107C42X5-157C42X5-257C42X5-35 Maximum Frequency (MHz)10066.74028.6 Maximum Access Time (ns)8101520 Minimum Cycle Time (ns)10152535 Minimum Data or Enable Set-Up (ns)3467 Minimum Data or Enable Hold (ns)0.5112 Maximum Flag Delay (ns)8101520
Operating Current (I CC2) (mA) @ freq=20MHz Commercial45454545 Industrial50505050
CY7C4425CY7C4205CY7C4215CY7C4225CY7C4235CY7C4245 Density64 x 18256 x 18512 x 181K x 182K x 184K x 18
Packages68-pin PLCC
64-pin TQFP
(10x10/14x14)
68-pin PLCC
64-pin TQFP
(10x10/14x14)
68-pin PLCC
64-pin TQFP
(10x10/14x14)
68-pin PLCC
64-pin TQFP
(10x10/14x14)
68-pin PLCC
64-pin TQFP
(10x10/14x14)
68-pin PLCC
64-pin TQFP
(10x10/14x14)
Pin Definitions
Signal Name Description I/O Function
D0–17Data Inputs I Data inputs for an 18-bit bus
Q0–17Data Outputs O Data outputs for an 18-bit bus
WEN Write Enable I Enables the WCLK input
REN Read Enable I Enables the RCLK input
WCLK Write Clock I The rising edge clocks data into the FIFO when WEN is LOW and the FIFO is not
Full. When LD is asserted, WCLK writes data into the programmable flag-offset
register.
RCLK Read Clock I The rising edge clocks data out of the FIFO when REN is LOW and the FIFO is not
Empty. When LD is asserted, RCLK reads data out of the programmable flag-off-
set register.
WXO/HF Write Expansion
Out/Half Full Flag O Dual-Mode Pin:
Single device or width expansion - Half Full status flag.
Cascaded - Write Expansion Out signal, connected to WXI of next device.
EF Empty Flag O When EF is LOW, the FIFO is empty. EF is synchronized to RCLK. FF Full Flag O When FF is LOW, the FIFO is full. FF is synchronized to WCLK.
PAE Programmable
Almost Empty O When PAE is LOW, the FIFO is almost empty based on the almost-empty offset value programmed into the FIFO. PAE is asynchronous when V CC/SMODE is tied to V CC; it is synchronized to RCLK when V CC/SMODE is tied to V SS.
PAF Programmable
Almost Full O When PAF is LOW, the FIFO is almost full based on the almost full offset value programmed into the FIFO. PAF is asynchronous when V CC/SMODE is tied to V CC; it is synchronized to WCLK when V CC/SMODE is tied to V SS.
LD Load I When LD is LOW, D0 - 17 (O0 - 17) are written (read) into (from) the programma-
ble-flag-offset register.
FL/RT First Load/
Retransmit I Dual-Mode Pin:
Cascaded - The first device in the daisy chain will have FL tied to V SS; all other devices will have FL tied to V CC. In standard mode of width expansion, FL is tied to V SS on all devices.
Not Cascaded - Tied to V SS. Retransmit function is also available in standalone mode by strobing RT.
WXI Write Expansion
Input I Cascaded - Connected to WXO of previous device.
Not Cascaded - Tied to V SS.
Maximum Ratings
(Above which the useful life may be impaired. For user guide-lines, not tested.)
Storage T emperature ....................................?65°C to +150°C Ambient Temperature with
Power Applied.................................................?55°C to +125°C Supply Voltage to Ground Potential.................?0.5V to +7.0V DC Voltage Applied to Outputs
in High Z State.....................................................?0.5V to +7.0V DC Input Voltage.................................................?3.0V to +7.0V Output Current into Outputs (LOW).............................20 mA Static Discharge Voltage. (2001)
(per MIL-STD-883, Method 3015)
Latch-Up Current.....................................................>200 mA
RXI Read Expansion
Input I Cascaded - Connected to RXO of previous device.
Not Cascaded - Tied to V SS.
RXO Read Expansion
Output
O Cascaded - Connected to RXI of next device.
RS Reset I Resets device to empty condition. A reset is required before an initial read or write
operation after power-up.
OE Output Enable I When OE is LOW, the FIFO’s data outputs drive the bus to which they are con-
nected. If OE is HIGH, the FIFO’s outputs are in High Z (high-impedance) state.
V CC/SMODE Synchronous
Almost Empty/
Almost Full Flags I Dual-Mode Pin
Asynchronous Almost Empty/Almost Full flags - tied to V CC.
Synchronous Almost Empty/Almost Full flags - tied to V SS.
(Almost Empty synchronized to RCLK, Almost Full synchronized to WCLK.)
Pin Definitions (continued)
Signal Name Description I/O Function
Operating Range
Range
Ambient
Temperature V CC
Commercial0°C to +70°C 5V ± 10%
Industrial[1]?40°C to +85°C 5V ± 10% Electrical Characteristics Over the Operating Range[2]
Parameter Description Test Conditions 7C42X5-107C42X5-157C42X5-257C42X5-35
Min.Max.Min.Max.Min.Max.Min.Max.Unit
V OH Output HIGH Voltage V CC = Min.,
I OH = ?2.0 mA
2.4 2.4 2.4 2.4V
V OL Output LOW Voltage V CC = Min.,
I OL = 8.0 mA
0.40.40.40.4V V IH[3]Input HIGH Voltage 2.2V CC 2.2V CC 2.2V CC 2.2V CC V V IL[3]Input LOW Voltage?3.00.8?3.00.8?3.00.8?3.00.8V I IX Input Leakage
Current
V CC = Max.?10+10?10+10?10+10?10+10μA
I OS[4]Output Short
Circuit Current V CC = Max.,
V OUT = GND
?90?90?90?90mA
I OZL I OZH Output OFF,
High Z Current
OE > V IH,
V SS < V O < V CC
?10+10?10+10?10+10?10+10μA
I CC2[5]Operating Current V CC = Max.,
I OUT = 0 mA Com’l45454545mA Ind50505050mA
I SB[6]Standby Current V CC = Max.,
I OUT = 0 mA Com’l10101010mA Ind15151515mA
Notes:
1.T A is the “instant on” case temperature.
2.See the last page of this specification for Group A subgroup testing information.
3.The V IH and V IL specifications apply for all inputs except WXI, RXI. The WXI, RXI pin is not a TTL input. It is connected to either RXO, WXO of the
previous device or V SS.
4.T est no more than one output at a time for not more than one second.
5.Input signals switch from 0V to 3V with a rise/fall time less than 3 ns, clocks and clock enables switch at 20 MHz, while the data inputs switch at 10 MHz.
Outputs are unloaded.
6.All input signals are connected to V CC. All outputs are unloaded.
Notes:
7.T ested initially and after any design or process changes that may affect these parameters.8.C L = 30 pF for all AC parameters except for t OHZ .9.C L = 5 pF for t OHZ .
Capacitance [7]
Parameter
Description
Test Conditions
Max.Unit C IN Input Capacitance T A = 25°C, f = 1 MHz,V CC = 5.0V
5pF C OUT
Output Capacitance
7
pF
AC Test Loads and Waveforms [8, 9]
3.0V 5V OUTPUT
R11.1K ?
R2680?
C L
INCLUDING JIG AND SCOPE
GND
90%10%
90%10%
<3ns
<3ns
OUTPUT
1.91V Equivalent to:
THé EVENIN EQUIVALENT
42X5–4
410?
ALL INPUT PULSES
42X5–5
Switching Characteristics Over the Operating Range
Parameter Description
7C42X5-10
7C42X5-157C42X5-257C42X5-35Min.
Max.Min.
Max.Min.
Max.Min.
Max.Unit t S Clock Cycle Frequency 10066.74028.6MHz t A Data Access Time 28
210
215
220
ns t CLK Clock Cycle Time 10152535ns t CLKH Clock HIGH Time 4.561014ns t CLKL Clock LOW Time 4.561014ns t DS Data Set-Up Time 3467ns t DH Data Hold Time 0.5112ns t ENS Enable Set-Up Time 3467ns t ENH Enable Hold Time 0.5112ns t RS Reset Pulse Width [10]10152535ns t RSR Reset Recovery Time
8
10
15
20
ns t RSF Reset to Flag and Output Time 10
15
25
35
ns t PRT Retransmit Pulse Width 12152535ns t RTR Retransmit Recovery Time
12152535ns t OLZ Output Enable to Output in Low Z [11]0000ns t OE Output Enable to Output Valid 3738312315ns t OHZ Output Enable to Output in High Z [12]3
73
83
123
15ns t WFF Write Clock to Full Flag 8101520ns t REF Read Clock to Empty Flag
8101520ns t PAFasynch
Clock to Programmable Almost-Full Flag [12]
(Asynchronous mode, V CC /SMODE tied to V CC )
1216
20
25
ns
t P AFsynch Clock to Programmable Almost-Full Flag
(Synchronous mode, V CC /SMODE tied to V SS )8101520ns t P AEasynch Clock to Programmable Almost-Empty Flag [12] (Asynchronous mode, V CC /SMODE tied to V CC )12162025ns t P AEsynch Clock to Programmable Almost-Full Flag
(Synchronous mode, V CC /SMODE tied to V SS )8101520ns t HF Clock to Half-Full Flag 12162025ns t XO Clock to Expansion Out 7
10
15
20
ns t XI Expansion in Pulse Width 3 6.51014ns t XIS Expansion in Set-Up Time
4.551015ns t SKEW1Skew Time between Read Clock and Write Clock for Full Flag
561012ns t SKEW2Skew Time between Read Clock and Write Clock for Empty Flag
561012ns t SKEW3
Skew Time between Read Clock and Write Clock for Programmable Almost Empty and Pro-grammable Almost Full Flags.
1015
18
20
ns
Switching Characteristics Over the Operating Range (continued)
Parameter Description
7C42X5-10
7C42X5-157C42X5-257C42X5-35Min.
Max.Min.
Max.Min.
Max.Min.
Max.Unit Switching Waveforms
Notes:
10.Pulse widths less than minimum values are not allowed.11.Values guaranteed by design, not currently tested.
12.P AFasynch , t PAEasynch , after program register write will not be valid until 5 ns + t P AF(E).
13.t SKEW1 is the minimum time between a rising RCLK edge and a rising WCLK edge to guarantee that FF will go HIGH during the current clock cycle. If the time between the
rising edge of RCLK and the rising edge of WCLK is less than t SKEW1, then FF may not change state until the next WCLK edge.
Write Cycle Timing
t CLKH
t CLKL
NO OPERATION
t DS
t SKEW1t ENS
WEN
t CLK
t DH
t WFF
t WFF t ENH
WCLK
D 0–D 17
FF
REN
RCLK
42X5–6
[13]
Notes:
14..t SKEW2 is the minimum time between a rising WCLK edge and a rising RCLK edge to guarantee that EF will go HIGH during the current clock cycle. It the time between the
rising edge of WCLK and the rising edge of RCLK is less than t SKEW2, then EF may not change state until the next RCLK edge.15.The clocks (RCLK, WCLK) can be free-running during reset.
16.After reset, the outputs will be LOW if OE = 0 and three-state if OE = 1.
Switching Waveforms (continued)
Read Cycle Timing
t CLKH
t CLKL
NO OPERATION
t SKEW2
WEN
t CLK
t OHZ
t REF
t REF
RCLK
Q 0–Q 17
EF
REN
WCLK
OE
t OE
t ENS
t OLZ
t A
t ENH
VALID DATA
42X5–7
[14]
t RS
t RSR
Q 0-Q 17
RS
t RSF
t RSF
t RSF
OE=1OE=0
REN,WEN,
LD
EF,PAE
FF,PAF,
HF
42X5–8
Reset Timing [15]
[16]
Notes:
17.When t SKEW2 > minimum specification, t FRL (maximum) = t CLK + t SKEW2. When t SKEW2 < minimum specification, t FRL (maximum) = either 2*t CLK + t SKEW2 or t CLK + t SKEW2.
The Latency Timing applies only at the Empty Boundary (EF = LOW).18.The first word is available the cycle after EF goes HIGH, always.
Switching Waveforms (continued)
D 0(FIRSTVALIDWRITE)First Data Word Latency after Reset with Simultaneous Read and Write
t SKEW2
WEN
WCLK
Q 0–Q 17
EF
REN
OE
t OE
t ENS
t OLZ
t DS
RCLK
t REF
t A
t FRL
D 1D 2D 3D 4
D 0
D 1
D 0–D 17
42X5–9
t A [18]
[17]
D1D0t ENS
t SKEW2
Empty Flag Timing
WEN
WCLK
Q 0–Q 17
EF
REN OE
t DS
t ENH
RCLK
t REF
t A
t FRL D 0–D 17
D0
t SKEW2
t FRL
t REF
t DS
t ENS
t ENH
42X5–10
t REF
[17][17]
Switching Waveforms (continued)
NEXT DATA READ
DATA WRITE
NO WRITE
DATA IN OUTPUT REGISTER
Full Flag Timing
FF
WCLK
Q 0–Q 17
REN
OE
RCLK
t A
D 0–D 17
DATAREAD
t SKEW1t DS
t ENS
t ENH
WEN
t WFF
t A
t SKEW1
t ENS
t ENH
t WFF
DATA WRITE
NO WRITE
t WFF
LOW
42X5–11
[13]
[13]
t ENH
Half-Full Flag Timing
WCLK
HF
REN
RCLK
t CLKH
t HF
t ENS HALF FULL+1OR MORE
t CLKL
t ENS
HALF FULL OR LESS
HALF FULL OR LESS
t HF
42X5–12
WEN
Notes:
19.PAE offset – n. Number of data words into FIFO already = n.20.PAE offset – n.
21.t SKEW3 is the minimum time between a rising WCLK and a rising RCLK edge for PAE to change state during that clock cycle. If the time between the edge of WCLK and the
rising RCLK is less than t SKEW3, then P AE may not change state until the next RCLK.
22.If a read is performed on this rising edge of the read clock, there will be Empty + (n – 1) words in the FIFO when PAE goes LOW.
Switching Waveforms (continued)
t ENH
Programmable Almost Empty Flag Timing
WCLK
PAE ]
REN
RCLK
t CLKH
t PAE
t ENS n+1 WORDS
IN FIFO
t CLKL
t ENS
t PAE
n WORDS IN FIFO
42X5–13
[19]
WEN
Note t ENH
WCLK
PAE
RCLK
t CLKH
t ENS t CLKL
t ENS
t PAEsynch
N +1WORDS
INFIFO
42X5–14
t ENH
t ENS t ENH
t ENS t PAEsynch
REN
WEN
WEN2
t SKEW3Note Programmable Almost Empty Flag Timing (applies only in SMODE (SMODE is LOW)
[21]
22
20
Notes:
23.PAF offset = m. Number of data words written into FIFO already = 64 – m + 1 for the CY7C4425, 256 – m + 1 for the CY7C4205, 512 – m + 1 for the
CY7C4215. 1024 – m + 1 for the CY7C4225, 2048 – m + 1 for the CY7C4235, and 4096 – m + 1 for the CY7C4245.24.PAF is offset = m.
25.64 – m words in CY7C4425, 256 – m words inCY7C4205, 512 – m word in CY7C4215. 1024 – m words in CY7C4225, 2048 – m words in CY7C4235, and
4096 – m words in CY7C4245.
26.64 – m + 1 words in CY7C4425, 256 – m + 1 words in CY7C4205, 512 – m +1 words in CY7C4215, 1024 – m + 1 CY7C4225, 2048 – m + 1 in CY74235,
and 4096 – m + 1 words in CY7C4245.
27.If a write is performed on this rising edge of the write clock, there will be Full – (m – 1) words of the FIFO when PAF goes LOW.28.PAF offset = m.
29.64 – m words in CY7C4425, 256 – m words in FIFO for CY7C4205, 512 – m word in CY7C4215. 1024 – m words in CY7C4225, 2048 – m words in CY7C4235,
and 4096 – m words in CY7C4245.
30.t SKEW3 is the minimum time between a rising RCLK and a rising WCLK edge for P AF to change state during that clock cycle. If the time between the edge of RCLK and the
rising edge of WCLK is less than t SKEW3, then P AF may not change state until the next WCLK rising edge.
Switching Waveforms (continued)
Note t ENH
WEN
WCLK
REN
RCLK
t CLKH
t PAF
t ENS t CLKL
t ENS
t PAF
42X5–15
FULL ?M WORDS
IN FIFO FULL ?M + 1 WORDS
IN FIFO Programmable Almost Full Flag Timing
[26]
PAF [24]
23
[25]
Note Note t ENH
WCLK
PAF
RCLK
t CLKH
t ENS FULL ?M WORDS
IN FIFO
t CLKL
t ENS
FULL-M+1? ORDS
INFIFO
42X5–16
t ENH
t ENS t ENH
t ENS t PAF
REN
WEN2
t SKEW3
t PAFsynch
[30]
28
27
WEN
Programmable Almost Full Flag Timing (applies only in SMODE (SMODE in LOW))
[29]
Note:
31.Write to Last Physical Location.
Switching Waveforms (continued)
t ENH Write Programmable Registers
LD
WCLK
t CLKH
t ENS
t CLKL
PAE OFFSET
D 0–D 17
WEN
t ENS
PAF OFFSET
PAE OFFSET
t CLK
D 0–D 11
t DS
t DH 42X5–17
t ENH
Read Programmable Registers
LD
RCLK
t CLKH
t ENS
t CLKL
PAE OFFSET
Q 0–Q 17
WEN
t ENS
PAF OFFSET
PAE OFFSET
t CLK
UNKNOWN
t A
42X5–18
Write Expansion Out Timing
WEN
WCLK
WXO
t CLKH
t ENS
Note t XO
t XO
42X5–19
31
Notes:
32.Read from Last Physical Location.33.Clocks are free running in this case.
34.The flags may change state during Retransmit as a result of the offset of the read and write pointers, but flags will be valid at t RTR .35.For the synchronous PAE and PAF flags (SMODE), an appropriate clock cycle is necessary after t RTR to update these flags.
Switching Waveforms (continued)
Read Expansion Out Timing
REN
WCLK
RXO
t CLKH
t ENS
Note t XO
t XO
42X5–20
32
Write Expansion InTiming
WCLK
WXI
t XI
t XIS
42X5–21
Read Expansion In Timing
RCLK
RXI
t XI
t XIS
42X5–22
Retransmit Timing REN/WEN
FL/RT
t PRT
t RTR
42X5–23
EF/FF and all async flags HF/PAE/PAF
[33, 34, 35]
Architecture
The CY7C42X5 consists of an array of 64 to 4K words of 18 bits each (implemented by a dual-port array of SRAM cells), a read pointer, a write pointer, control signals (RCLK, WCLK, REN, WEN, RS), and flags (EF, PAE, HF, PAF, FF). The CY7C42X5 also includes the control signals WXI, RXI, WXO, RXO for depth expansion.
Resetting the FIFO
Upon power-up, the FIFO must be reset with a Reset (RS) cycle. This causes the FIFO to enter the Empty condition sig-nified by EF being LOW. All data outputs go LOW after the falling edge of RS only if OE is asserted. In order for the FIFO to reset to its default state, a falling edge must occur on RS and the user must not read or write while RS is LOW.
FIFO Operation
When the WEN signal is active (LOW), data present on the D0–17 pins is written into the FIFO on each rising edge of the WCLK signal. Similarly, when the REN signal is active LOW, data in the FIFO memory will be presented on the Q0–17 out-puts. New data will be presented on each rising edge of RCLK while REN is active LOW and OE is LOW. REN must set up tENS before RCLK for it to be a valid read function. WEN must occur tENS before WCLK for it to be a valid write function. An output enable (OE) pin is provided to three-state the Q0–17 outputs when OE is deasserted. When OE is enabled (LOW), data in the output register will be available to the Q0–17 outputs after t OE. If devices are cascaded, the OE function will only output data on the FIFO that is read enabled.
The FIFO contains overflow circuitry to disallow additional writes when the FIFO is full, and underflow circuitry to disallow additional reads when the FIFO is empty. An empty FIFO maintains the data of the last valid read on its Q0–17 outputs even after additional reads occur.
Programming
The CY7C42X5 devices contain two 12-bit offset registers. Data present on D0–11 during a program write will determine the distance from Empty (Full) that the Almost Empty (Almost Full) flags become active. If the user elects not to program the FIFO’s flags, the default offset values are used (see Table 2). When the Load LD pin is set LOW and WEN is set LOW, data on the inputs D0–11 is written into the Empty offset register on the first LOW-to-HIGH transition of the write clock (WCLK). When the LD pin and WEN are held LOW then data is written into the Full offset register on the second LOW-to-HIGH tran-sition of the write clock (WCLK). The third transition of the write clock (WCLK) again writes to the Empty offset register (see Table 1). Writing all offset registers does not have to occur at one time. One or two offset registers can be written and then, by bringing the LD pin HIGH, the FIFO is returned to normal read/write operation. When the LD pin is set LOW, and WEN is LOW, the next offset register in sequence is written.
The contents of the offset registers can be read on the output lines when the LD pin is set LOW and REN is set LOW; then, data can be read on the LOW-to-HIGH transition of the read clock (RCLK).Flag Operation
The CY7C42X5 devices provide five flag pins to indicate the condition of the FIFO contents. Empty and Full are synchro-nous. PAE and PAF are synchronous if V CC/SMODE is tied to V SS.
Full Flag
The Full Flag (FF) will go LOW when device is Full. Write op-erations are inhibited whenever FF is LOW regardless of the state of WEN. FF is synchronized to WCLK, i.e., it is exclusive-ly updated by each rising edge of WCLK.
Empty Flag
The Empty Flag (EF) will go LOW when the device is empty. Read operations are inhibited whenever EF is LOW, regard-less of the state of REN. EF is synchronized to RCLK, i.e., it is exclusively updated by each rising edge of RCLK.
Programmable Almost Empty/Almost Full Flag
The CY7C42X5 features programmable Almost Empty and Al-most Full Flags. Each flag can be programmed (described in the Programming section) a specific distance from the corre-sponding boundary flags (Empty or Full). When the FIFO con-tains the number of words or fewer for which the flags have been programmed, the PAF or PAE will be asserted, signifying that the FIFO is either Almost Full or Almost Empty. See Table 2 for a description of programmable flags.
When the SMODE pin is tied LOW, the PAF flag signal transi-tion is caused by the rising edge of the write clock and the PAE flag transition is caused by the rising edge of the read clock.
Retransmit
The retransmit feature is beneficial when transferring packets of data. It enables the receipt of data to be acknowledged by the receiver and retransmitted if necessary.
The Retransmit (RT) input is active in the standalone and width expansion modes. The retransmit feature is intended for use when a number of writes equal to or less than the depth of the FIFO have occurred since the last RS cycle. A HIGH pulse on RT resets the internal read pointer to the first physical location of the FIFO. WCLK and RCLK may be free running but must be disabled during and t RTR after the retransmit pulse. With Table 1.Write Offset Register
LD WEN WCLK[36]Selection
00Writing to offset registers:
Empty Offset
Full Offset
01No Operation
10Write Into FIFO
11No Operation
Note:
36.The same selection sequence applies to reading from the registers. REN
is enabled and read is performed on the LOW-to-HIGH transition of RCLK.
every valid read cycle after retransmit, previously accessed data is read and the read pointer is incremented until it is equal to the write pointer. Flags are governed by the relative loca-tions of the read and write pointers and are updated during a retransmit cycle. Data written to the FIFO after activation of RT are transmitted also.
The full depth of the FIFO can be repeatedly retransmitted.
Width Expansion Configuration
The CY7C42X5 can be expanded in width to provide word widths greater than 18 in increments of 18. During width ex-pansion mode all control line inputs are common and all flags
are available. Empty (Full) flags should be created by ANDing the Empty (Full) flags of every FIFO. This technique will avoid ready data from the FIFO that is “staggered” by one clock cycle due to the variations in skew between RCLK and WCLK.Figure 1 demonstrates a 36-word width by using two CY7C42X5.
Table 2.Flag Truth Table.
Number of Words in FIFO
FF PAF HF PAE EF 7C4425 - 64 x 187C4205 - 256 x 18
7C4215 - 512 x 18000
H H H L L 1 to n [37 1 to n [37] 1 to n [37]H H H L H (n+1) to 32(n+1) to 128(n+1) to 256H H H H H 33 to (64 – (m+1))129 to (256 – (m+1))257 to (512 – (m+1))H H L H H (64 – m)[38] to 63(256 – m)[38] to 255(512 – m)[38] to 511H L L H H 64
256
512
L
L
L
H
H
Number of Words in FIFO
FF PAF HF PAE EF 7C4225 - 1K x 187C4235 - 2K x 18 7C4245 - 4K x 18000
H H H L L 1 to n
[37]
1 to n [37] 1 to n [37]H H H L H (n+1) to 512
(n+1) to 1024
(n+1) to 2048
H H H H H 513 to (1024 – (m+1))1025 to (2048 – (m+1))2049 to (4096 – (m+1))H H L H H (1024 – m)[38] to 1023(2048 – m)[38] to 2047(4096 – m)[38] to 4095H L L H H 1024
2048
4096
L
L
L
H
H
Notes:
37.n = Empty Offset (Default Values: CY7C4425 n = 7, CY7C4205 n = 31, CY7C4215 n = 63, CY7C4225/7C4235/7C4245 n = 127).38.m = Full Offset (Default Values: CY7C4425 n = 7, CY7C4205 n = 31, CY7C4215 n = 63, CY7C4225/7C4235/7C4245 n = 127).
Figure 1.Block Diagram of 64x36/256 x 36/512 x 36/1024 x 36/2048 x 36/4096 x 36 Synchronous FIFO Memory Used in a
Width Expansion Configuration.
42X5–24
FF
FF
EF EF
WRITECLOCK (WCLK)WRITEENABLE (WEN)
LOAD (LD)
PROGRAMMABLE(PAE)HALF FULL FLAG (HF)
FULL FLAG (FF)
7C44257C42057C42157C42257C42357C4235
7C44257C42057C42157C42257C42357C4235
18
36
DATAIN (D)RESET(RS)
18
RESET (RS)
READ CLOCK (RCLK)READ ENABLE (REN)OUTPUTENABLE (OE)PROGRAMMABLE(PAF)
EMPTYFLAG (EF)
18
DATAOUT (Q)
18
36
FIRST LOAD (FL)
WRITE EXPANSION IN (WXI)READ EXPANSION IN (RXI)
Depth Expansion Configuration (with Programmable Flags)
The CY7C42X5 can easily be adapted to applications requir-ing more than 64/256/512/1024/2048/4096 words of buffering.Figure 2 shows Depth Expansion using three CY7C42X5s. Maxi-mum depth is limited only by signal loading. Follow these steps:1.The first device must be designated by grounding the First Load (FL) control input.2.All other devices must have FL in the HIGH state.
3.The Write Expansion Out (WXO) pin of each device must be tied to the Write Expansion In (WXI) pin of the next device.
4.The Read Expansion Out (RXO) pin of each device must be tied to the Read Expansion In (RXI) pin of the next device.
5.All Load (LD) pins are tied together.
6.The Half-Full Flag (HF) is not available in the Depth Expansion Configuration.
7.EF , FF, PAE, and PAF are created with composite flags by ORing together these respective flags for monitoring. The composite PAE and PAF flags are not precise.
Figure 2.Block Diagram of 192 x 18/768 x 18/1536 x 18/3072 x 18/12288 x 18 Synchronous FIFO Memory
with Programmable Flags used in Depth Expansion Configuration.
42X5–23
WRITECLOCK (WCLK)WRITE ENABLE (WEN)RESET(RS)
LOAD (LD)
FF
PAF
PAF FF
EF
PAE
PAE
EF WXI RXI FIRSTLOAD (FL)
READCLOCK (RCLK)READ ENABLE (REN)OUTPUT ENABLE (OE)
WXO RXO 7C44257C42057C42157C42257C42357C4235PAF
FF EF
PAE WXI RXI
WXO RXO 7C44257C42057C42157C42257C42357C4235V CC
FIRSTLOAD (FL)
PAF
FF EF
PAE WXI RXI
WXO RXO 7C44257C42057C42157C42257C42357C4235V CC
FIRSTLOAD (FL)
DATAIN (D)
DATAOUT (Q)
Typical AC and DC Characteristics
Ordering Information 64 x 18 Synchronous FIFO
Speed
(ns)Ordering Code Package
Name
Package
Type
Operating
Range
10CY7C4425-10AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4425-10ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4425-10JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4425-10AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4425-10ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4425-10JI J8168-Lead Plastic Leaded Chip Carrier
15CY7C4425-15AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4425-15ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4425-15JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4425-15AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4425-15ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4425-15JI J8168-Lead Plastic Leaded Chip Carrier
25CY7C4425-25AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4425-25ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4425-25JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4425-25AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4425-25ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4425-25JI J8168-Lead Plastic Leaded Chip Carrier
35CY7C4425-35AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4425-35ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4425-35JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4425-35AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4425-35ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4425-35JI J8168-Lead Plastic Leaded Chip Carrier
256 x 18 Synchronous FIFO
Speed
(ns)Ordering Code Package
Name
Package
Type
Operating
Range
10CY7C4205-10AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4205-10ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4205-10JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4205-10AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4205-10ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4205-10JI J8168-Lead Plastic Leaded Chip Carrier
15CY7C4205-15AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4205-15ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4205-15JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4205-15AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4205-15ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4205-15JI J8168-Lead Plastic Leaded Chip Carrier
25CY7C4205-25AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4205-25ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4205-25JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4205-25AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4205-25ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4205-25JI J8168-Lead Plastic Leaded Chip Carrier
35CY7C4205-35AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4205-35ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4205-35JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4205-35AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4205-35ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4205-35JI J8168-Lead Plastic Leaded Chip Carrier
512 x 18 Synchronous FIFO
Speed
(ns)Ordering Code Package
Name
Package
Type
Operating
Range
10CY7C4215-10AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4215-10ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4215-10JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4215-10AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4215-10ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4215-10JI J8168-Lead Plastic Leaded Chip Carrier
15CY7C4215-15AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4215-15ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4215-15JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4215-15AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4215-15ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4215-15JI J8168-Lead Plastic Leaded Chip Carrier
25CY7C4215-25AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4215-25ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4215-25JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4215-25AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4215-25ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4215-25JI J8168-Lead Plastic Leaded Chip Carrier
35CY7C4215-35AC A6564-Lead 14x14 Thin Quad Flatpack Commercial CY7C4215-35ASC A6464-Lead 10x10 Thin Quad Flatpack
CY7C4215-35JC J8168-Lead Plastic Leaded Chip Carrier
CY7C4215-35AI A6564-Lead 14x14 Thin Quad Flatpack Industrial
CY7C4215-35ASI A6464-Lead 10x10 Thin Quad Flatpack
CY7C4215-35JI J8168-Lead Plastic Leaded Chip Carrier